Temperature control of catalytic reactions



Aug. 28, 1945. w. A. WURTH TEMPERATURE CONTROL OF CATALYTIC REACTIONS Filed Aug. 9, 1941 2 Sheets-Sheet 2 u 'Il vll Il!!! n v Patented ug. 28, 1.945

NTRIIgJSOF CATALYTIC TEMPERATURE CO ACTIO Walter A. Wurth, Cranford, N. J., assigner to Standard Oil Development Company, a corporation o! Delaware 9 Claims.

This invention relates to controlling the temperature in chemical reactions and more particularly relates to controlling the temperature of exothermic reactions involving powdered catalyst where a suspension of powdered catalyst in i'lnely divided i'orm is passed upwardly with a reactant or reactants through a reaction zone or chamber.

In exothermic reactions involving the use of catalyst it is important to remove the heat from the catalyst to prevent overheating of the catalyst and reactants. In certain catalytic reactions overheating of the catalyst partially or totally deactivates the catalyst depending on the amount of overheating. It the temperatures are too high, the yields of desired products are decreased due to side reactions.

Heretoi'ore, heat exchangers were used which were separate from and outside the reaction zones. According to my invention the heat exchange equipment is entirely arranged in the same shell or vessel which houses the reaction zone. In this way the piping requirements are simplified and less costly. Expansion joints are eliminated. Also less pressure drop is involved in circulating the material to be cooled by my arrangement oi' heat exchange equipment.

According to my invention, exothermic catalytic reactions are carried out under controlled conditions so that the catalyst is not overheated and the reactants are maintained at the desired temperature during the reaction. For example, in reactions involving the reduction of hydrocarbons where reacting carbon monoxide and hydrogen in the presence of catalyst. the reactants are mixed with powdered or ilnely divided catalyst particles to i'orm a suspension which is passed upward through an enlarged reaction chamber. In such reaction chambers there is an evolution of heat due to the reaction and it is desirable to remove the heat to maintain the reaction at the desired temperature.

In a reaction chamber constructed to embody my invention I provide means for removing heat from the reaction chamber by means oi tubes. certain oi' the tubes being so arranged to contact the catalyst particles and reactants or suspend ing gases or vapors as they pass upward through the reaction chamber. The tubes form part of s boiler. such as a steam boiler or the like. the tubes being vertically arranged and being in communication with steam and water drums. It is advantageous to have the boiler tubes vertically arranged because this arrangement permits downward flow of the catalyst particles without undue obstructions.

Application August 9. 1941, Serial No. 406,226

The suspension oi catalyst particles in reactant gas or gases is introduced into the bottom portion oi the reaction zone or chamber and passes upward through a central vertical passageway which is formed by arranging a circle ol vertical tubes. Ii' desired, the tubes may be provided with fins, or metal or other inserts may nbe placed between the tubes to form the reaction chamber. Or. the tubes alone may be used. The tubes form a smooth passageway for the suspension and it will be seen that the suspension including the catalyst particles is in direct contact with the tubes forming part oi' the boiler. As the suspension passes upwardly the catalyst particles are in intimate contact with the vapors or gases and the mixture is in a turbulent condition. In this way heat is absorbed by the iluid in the inner circle of tubes and the temperature of the catalyst particles is prevented from rising too high. 'I'he 'reaction zone formed by the inner circle of tubes is arranged entirely within a shell or container. The lower ends of the central tubes communicate With a water drum in the shell or container and the upper ends oi' the central tubes communicate with a steam drum in the shell or container. As the suspension leaves the top of the reaction chamber, it passes into a larger volume and the velocity of the gases or vapors is decreased due to the enlarged volume. Due to the decrease in velocity the catalyst particles are dropped out of the suspension and fall down over additional vertically arranged tubes communicating with the water and steam drums above described. By varying the velocity of the gases or vapors, the amount of catalyst removed from the suspension may be varied.

Certain oi' the last-mentioned set oi' tubes form a larger outer circle concentric with the ilrst circle of tubes but arranged closer to the wall o! the reaction zone or chamber. Other tubes are vertically arranged in the space between the concentric circles of tubes. At the upper and lower portions the tubes of the larger circle are bent inwardly toward the steam drum and water drum, respectively to provide slightly inclined tube portions with which the falling catalyst particles are con;

tacted and heat exchange is effected between the fluid in the tubes and the catalyst particles. The other vertical tubes between the inner and outer circles of tubes have bent portions for connecting with the respective drums.

My invention may be used where exothermic catalytic reactions are involved such as polymerization, hydrogenation. the reduction of carbon monoxide by hydrogen and other chemical reaction or where endothermic catalytic reactions are used s as cracking. reforming. dehydrogenating.e Inendothermicreactionsheatissuppliedtothereactionbymeansofthedrumsand tubes above dcribed. My invention may also be used to regenerate catalyst particles which have beenusedinthecatalytic conversionoihydrocarbons. In cracking. dehydrogenation, Polymerization, alkylation. etc.. carbonaceous or organic ma tealisdepositedonthecatalystparticlesandii these catalyst particles are to be reused they are preferably regenerated. Preferably the carbonaceous material is removed by burnixu with air or other oxidizing agent. Astheregmerationoverationisanexothenniconaltisnecessaryto carefully control the temperature during regeneration and my invention is especially adapted for such control.

In my invention desired amounts oi the separatedcatalystparriciesarerecycledtothereactlonzoneorchamberandtherestofthecatalyst particles together with the gaseous or vaporous products oi the reaction pass overhead and the catalyst particles ane separated from the vaporous or gaseous products of reaction in any suitable manner.

Inthe drawings: l

Fig. l represents one form of apparatus for carrying out an exothermic catalytic reaction or for regenerating fouled catalyst particles:

Fig. 2 represents apparatus adapted to carry out catalytic conversions of hydrocarbons and includes a regeneration zone or chamber;

Fig. 3 is an enlarged vertical cross section taken through a reaction zone or chamber embodying my invention; and

Fig. 4 represents a horizontal transverse cross section taken on line IV-IV on Fig. 3.

Referring now to the drawings and to Figs. l, 3 and 4, the reference character III designates a line for conducting a suspension oi' solid catalyst particles in gaseous or vaporous reactants. The suspension is introduced into the bottom portion o! a vessel or shell I2 having a reaction sone i3. Where an exothermic catalytic reaction is involved. it is often n to prevent overheating of the reactants and overheating of the catalyst particles, this may be accomplished by removing some of the heat of reaction from the reaction zone or chamber during. the reaction. The reaction zone or chamber I2 is shown in greater detail in Figs. 3 and 4 and attention is directed to these ngures in connection with the following description.

The suspension as it enters the vessel I2 passes upwardly through the central vertical passageway Il which forms the reaction zone. The reaction zone Il is formed by sleeve Il, vertically arranged tubes it and a top sleeve iii provided with an inclined top flange 2B. The suspension oi' catalyst particles in the gaseous i'luid passes upwardly through this passageway or zone. During its upward passage the velocity of the gases or vapors is so adjusted that the catalyst particles are fluidized, that is the mixture of catalyst particles and gas or vapors take on the appearance oi' a liquid. In iluidized form the mixture is in turbulent condition and there is intimate contact between the catalyst particles and gas or vapors and the heat exchange tubes IB. As the iluidized mixture leaves the upper sleeve i8 there is a decrease in the velocity of the suspension due .to the enlarged volume 2| at the top of the reaction chamber. Due to this decrease in velocity some of the cata lyst particles are separated and dropped from the :,ssaese suspension and tall through the annular chamber 22 arranged between reaction sone il and shell l2 aswillbepresentlydescrlbed. Therestofthe catalyst particles and the products oi reaction pals upwardly and leave the top o! the vessel I2 throughoutletllnellandareturthertreatedas :alliantie further described hereafter in greater The vertical central passageway or reaction :one il is formed by the vertical tubes II arranged in parallel relation and substantially in a circle. Inordertoprovldeasmooth ,inserts 2l may be provided between the tubes. However, themsertsmaybeomitted.iidesired. Thetubes ltmaybeprovidedwithnnsto provide acentral passageway or reaction chamber Il. The lower ends of the tubes il are bent outwardly away from reaction sone Il as at 2l and communicate withanannularliquiddrumllarrangedinthe lower portion of the shell I2. It will be noted that the sleeve Il is provided as a conduit for carrying the catalyst-vapor mixture upwardly beyond the bent portions 2l oi' the tubes il so that the suspension will continue upwardly through the reaction sone or central passageway il. Tho upper ends or the central tubes II are bent outwardly away from none I3 as at Il and. communicatc with an annular drum 8l arranged in the upper portion of the shell i2. Ihe lower part of named sleeve il is arranged to extend below the bent portions Il oi the tubes to form a continuation of the passageway Il formed by the tubes il to carry the suspension upward beyond the drum 20. Y

A larger concentric circle oi tubes I1 is provided in annular chamber 22 which communicates with the drums 34 and lt and which is arranged closer to the wall of the shell or vessel I2. Each tube forming the outer circle has a vertical porltion 88, an inclinedupper portion l2 and a lower manned portion The upper portions I2 communicate with the drum 3B and the lower portions communicate with the drum Il. Where water is used as the heat exchange medium, drum 3B is a steam drum and lower drum 3l is a water drum.

Arranged between tubes I8 and Il are intermediate tubes ll which have inclined upper portions leading to drum 3B and inclined lower portions 41 leading to drum 34. See the cross section in Figure 4 for the arrangement of the intermediate tubes II. As the separated catalyst particles tall, they contact the heat exchange tubes and are cooled. -Fluidizing gas is preferably introduced into the bottom portion of shell I2 at a plurality of points as Il to maintain the separated catalyst particles in annular chamber 22 in a iluidized condition whereby the catalyst particles are in a turbulentcondition and well mixed and a substantially uniform temperature is maintained throughout the mass. By maintaining a tluidized condition of the catalyst particles good heat exchange between the catalyst and tubes is obtained.

It will be seen from the drawings and from an inspection of Figure 3 that the nange 20 on the trip sleeve IB extends over the steam drum 36 so that the separated catalyst particles are returned in the annular chamber 22. The catalyst particles which are dropped from the suspension pass downwardly and contact the top bent portions l2 oi' the outer tubes Il and the top bent portions PB oi' certain of the intermediate tubes I5. The process is preferably so carried out that the annular chamber 22 is substantially completely lled assasse with nuidized catalyst. When smaller amounts or levels o! iluidized catalyst are maintained in chamber 22. baiiles may be used to direct the ralling catalyst particles as desired.

The cooled uidized catalyst particles after having passed in heat exchange relation with the tubes il and 4l move downward into the space I2 in the lower portion oi' the shell or vessel i2 and then Ipa'ss through annular opening It between sleeve i4 and shell Il where they are picked up by the incoming catalyst and feed mixture and again passed upwardly through the verticallentral passageway forming reaction chamber An inlet line I4 for liquids is provided having a -pump It for introducing liquid into the lower drum I4. The upper drum 86 communicates with another drum BB situated outside of the shell i2 through lines 82. DrvY steam is withdrawn from drum 6B by means of line B4.

The products of reaction in vapor or sas form and catalyst particles passing through line 24 (see Figure 1) are introduced into a suitable separating system such as a cyclone separator Bl for separating solids from vapors and gases. While only one cyclone separator is shown. it is to be understood that a plurality of cyclone separators is preferably used and in addition a Cottrell precipitator or filter means may be used for removing the catalyst lines from the gases and vapors leaving the cyclone separators. The separated gases and vapors pass overhead through line i2 and are further treated as desired to separate valuable constituents therefrom. The solid catalyst particles are collected in the bottom oi the separating means B8 and are passed through line 14 to a hopper 1B from which they are withdrawn through line l1. In the catalytic reactions which are carried out according to my invention the catalyst particles become inactivated or fouled after being used for a certain time and the catalyst particles are regenerated in any suitable-manner.

In a process as above described the reaction zone il and vessel I2 may be used for reactions involving the reduction of carbon monoxide by hydrogen. for example, in the presence oi suitable catalyst. In this reaction the catalyst is not fouled rapidly and may be recirculated in the reaction zone I3 a number of times before it need be regenerated. The catalyst particles are preferably of a size of about 100 to 400 standard mesh.

In Figure 2 of the drawings I have shown apparatus adapted for catalytic conversions of hydrocarbons such as cracking, dehydrogenation, alkylation, isomerization, etc. The catalytic cracking of higher boiling hydrocarbons to form lower boiling hydrocarbons will be specifically described. A hopper |30 is provided into which fresh catalyst particles are introduced through line I3l. For catalytic cracking oi' hydrocarbons any suitable catalyst may bc used such as acid treated bentonites. synthetic clays, synthetic gels containing silica and alumina or silica and magnesia, etc. The catalyst is preferably in finely divided form having a size or about 100 and 400 standard mesh. The catalyst particles in the bottom of the hopper |30 are uidized or rendered mobile by the introduction of a suitable inert gas such as steam through line |32. The fiuidized catalyst particles flow into an elongated standpipe |34 which is preferably provided with lines ll for introducing a fiuidizing medium into the standpipe to maintain the catalyst particles in a fluid condition. 'I'he bottom of the standpipe |34 is provided with a valve IIB which may be manually or automatically operated to control the amount o! catalyst particles fed from the stand- Pipe.

The tluidized catalyst particles in the standpipe act as a liquid and provide s. head of pressure for forcing the catalyst particles and reactants through the system. For example, with a standpipe ot about feet a pressure of about 20 pounds per square inch is obtained at the bottom of the standpipe with tluidized clay particles.

The catalyst particles from the standpipe are fed into a mixing zone |42 where they are mixed with hydrocarbon vapors and gases introduced through line |44. The mixture of catalyst particles and hydrocarbon vapors and gases are passed through line |40 and into the lower portion of an enlarged vertically arranged reaction chamber |48. As the cracking of hydrocarbons is an endothermic reaction, it is not necessary to providea cooling means in the reaction chamber HI8. It desired. tubes may be arranged within the reaction chamber |48 similar to that shown in vessel i2 for supplying heat to the reactants and catalyst in the reaction chamber |48.

Due to the enlarged diameter of the reaction chamber |48, the velocity of the catalyst feed mixture is reduced as it enters the reaction chamber and due to the reduction in velocity there is some slippage between the catalyst particles and the gases and vapors passing through the reaction chamber |48. By this decrease in velocity, there is an increase in the concentration of the catalyst particles in the hydrocarbon vapors and gases over that in the inlet pipe |48. The suspension in passing through the reaction chamber |48 is in a turbulent condition and good mixing and good contact is obtained between the catalyst particles and the hydrocarbon vapors and gases.

The products oi' reaction and catalyst particles leave the top of the reaction chamber |48 through line |52 and are passed to a separating system |54 which is sho'wn as a cyclone separator. Preferably more than one cyclone separator is used. The separated products of reaction in vapor form pass overhead through line I 5B and are passed to suitable equipment such as fractionating means for separating desired constituents from higher boiling hydrocarbons.

The catalyst particles during the cracking of the hydrocarbons become coated with carbonaceous or organic material which reduces the activity of the catalyst particles. Before reusing the catalyst particles, it is preferable to regenerate them. However, in some instances a portion of the unregenerated catalyst may be recycled to the reaction ychamber |48. The catalyst particles coated with carbonaceous material rail to the bottom of the separator |54 and are withdrawn therefrom through line IBB. From line |58, the particles are introduced into a` hopper |62 with the pipev |58 extending below the level of catalyst particles in the hopper |62.

The catalyst particles in the hopper |62 are preferably tluidized by the introduction of steam or other suitable gas through line |66. Suillcient amounts of fiuidizing gas are introduced to fluidize the catalyst particles as above described in connection with the other hoppers. The fiuidized catalyst particles flow into a standpipe |88 which is also provided with lines |68 for the addition of further amounts of iluidizing gas to maintain the catalyst particles in fluid condition in the standpipe. The lower end of the standpipe IGI is provided with a valve |12 which may be manual or automatically operated to control the amount of catalyst particles leaving the outlet or the standpipe |86- The catalyst particles from the standpipe |88 are fed into a mixing zone |14 where they are mixed with an additional amount of steam introduced through line |18 to form a suspension ot the fouled catalyst particles. The suspension is passed through line |11 and air is introduced through line |18 to supply an oxidizing agent for the carbonaceous material on the catalyst particles. The suspension is then passed into the lower portion of a regeneration zone or chamber |82 (diagrammatically shown) which is of substantially the same construction as the reaction zone II and vessel I2 described in connection with Figures l, 3 and 4.

The regeneration oi' catalyst particles separated from cracked products is an exothermic reaction and during regeneration it is necessary to control the temperature and to prevent the temperature from rising too high. For example, where acid activated clays are used as catalysts, it is necessary to maintain the top temperature below about 1100 F. With some catalysts higher temperatures may be used. However. it is necessary to control the temperature during regeneration and the boiler construction described in connection with reaction chamber I2 is especially adapted for controlling the temperature during regeneration in the regeneration zone |80 arranged in vessel |82. The regeneration zone |80 is formed by a 'circle of tubes |88 and due to the fluidized condition, the catalyst particles have intimate contact with tubes |88 and are cooled. As the fiuidized catalyst passes upward into space |84, the velocity is reduced and the catalyst particles pass into annular chamber |88 where they contact other cooling tubes |88 similar to those above described in connection with vessel I2. The separated catalyst particles in annular chamber |88 are also fluidized and returned to regeneration zone |80 to assist in cooling during regeneration. The amount of regenerated catalyst recycled is controlled to obtain the desired temperature during regeneration. From the above it will be seen that the catalyst particles are regenerated and cooled in one apparatus.

The regenerated catalyst particles and combustion gases pass overhead through line |88 and are introduced into a separating system |80 which is shown on tle drawings as a cyclone separator. Preferably more than one cyclone separator is used and in addition an electric preoipitator may be used to remove the residual flne catalyst particles from the outgoing combustion gases. The combustion or regeneration gases pass overhead through line |82 and the regenerated catalyst particles are withdrawn from the bottom of the separator |90 by means of line |94 which preferably extends beneath the level of the catalyst particles in the hopper |00. The catalyst particles from hopper |80 are introduced into the standpipe |34 from which they are introduced into the reaction chamber |48 as above described.

A specific example for the reduction of carbon monoxide with hydrogen will now be given. A mixture of carbon monoxide and hydrogen in the proportion oi' about l mol of carbon monoxide to 2 mois of hydrogen is introduced into reaction zone Iil through line |0. The feed gas preferably contains about 95% of the reactants,

the remainder being nitrogen or other inert gas assaesc and free of sulfur. The catalyst which is mixed with the gaseous feed is oi' the Fischer-Iropsch type containing about 30% by weight oi' cobalt and a metal oxide promoter, such as magnesio.. deposited on kieselguhr. The catalyst has a particle size of about to 400 mesh. The catalyst is preferably in aerated form. As an aerating gas. a small amount oi hydrogen is used.

The temperature in the reaction zone Il is maintained at about 370 F'. Thereduction of carbon monoxide is exothermic and the liquid in the tubes in the reaction zone I8 and vessel I2 acts to maintain the temperature in the reaction zone within the desired limits. Heat is absorbed by the liquid in the tubes and in this way the temperature of the catalyst particles is reduced. The mixture ol' catalyst particles and gases to be reacted enter the vessel I2 at a temperature of about F.. and should not be allowed to exceed about 300 F. before admission to the reaction chamber i8.

Another example involving the catalytic cracking of hydrocarbons will be now given. Hydrocarbon vapors such as gas oil vapors are introduced into mixing zone |42 where they are mixed with acid activated 'bentonite oi a standard mesh be tween about 100 and 400. The ratio oi' catalyst to oil vapors is about 4 parts of catalyst to 1 part oi' oil vapors by weight. The mixture as it enters the`reactlon zone |48 is at a temperature of about 850 F. to 975 F'. In the reaction zone |48 the catalyst particles and the oil vapors are thoroughly mixed and maintained in intimate contact to effect the desired extent o1' conversion. The residence time of the oil vapors in the reaction zone is about i5 seconds.

The reaction products and the catalyst particles pass overhead through line |82 and the vaporous reaction products are separated from catalyst particles in the separating means |84. The reaction products in vapor form pass overhead through line |50 to suitalble fractionating equipment to recover desired lighter constituents from higher boiling constituents.

The separated catalyst particles being coated with carbonaceous deposits are preferably regenerated. Tlie catalyst particles and air in admixture with steam are introduced into the lower portion of the regeneration zone |80 in vessel |82 for burning off the carbonaceous deposits and regenerating the catalyst particles. The regeneration is an exothermic reaction and when an acid activated clay such as bentonite is used as a catalyst it is necessary to control the temperature and maintain it below about 1100 F. to prevent sintering and deactivatlng of the catalyst particles. The boiler as described in connection with the reaction chamber i3 is the construction used in the regeneration zone |80 to control the temperature of the catalyst particles during regeneration.

The air and fouled catalyst particles pass upward through regeneration zone |80 as a fiuidized mass. As the fluidized mass reaches enlarged space |84 there is a decrease in the velocity and catalyst particles are dropped into annular charnber |80 where they are fiuidized by introduction of a suitable fluidizing gas such as steam. The regenerated catalyst particles are .cooled by contacting the tubes |86 and due to the fluidized condition there is intimate contact between the catalyst particles and heat exchange tubes. The cooled regenerated catalyst particles are then recycled to the regeneration zone |80 and assist in controlling the temperature of additional fouled catalyst being regenerated in regeneration zone itil.

The regenerated catalyst particles which pass overhead through line |88 are separated in cyclone |90 and are then returned to the catalyst hopper |30 for reuse in another cracking operation.

The boiler tubes and drums are supported in the shell in any suitable manner as by supports 200. The sleeves i4 and I8 may be welded or otherwise attached to the tubes or drums in the shell.

While in Figure 4 I have shown rows of spaced tubes, it is to be understood that the tubes may be so arranged to lili in the spaces between tubes 45 and 31 to substantially completely ll the vessel I2 with vertically arranged heat exchange tubes.

While examples have been given involving the reduction of carbon monoxidewith hydrogen and catalytic cracking oi' hydrocarbons and several reactions have 4been described as being capable oi' being carried out in a reaction zone including an internal boiler of construction, it is to be understood that these are by way of illustration only and changes and modifications may be made without departing from the spirit of my invention.

I claim:

l. A process for carrying out chemical reactions which comprises passing a fiuidized mass oi solid finely divided particles in a gaseous medium upwardly through a confined passageway formed by heat exchange tubes arranged and terminating within a vessel, passing the fiuidized mass into a larger space after it leaves said passageway so that some oi the particles drop out of the ,fiuidized mass and are contacted with additional tions which comprises passing a fiuldized mass oi' solid finely divided particles in a gaseous medium through a confined passageway formed by heat exchange tubes arranged and terminating within a vessel, removing some of the catalyst particles from the iiuidized mass after it leaves said passageway and passing the removed catalyst particles over additional heat exchange tubes, then mixing the particles with additional gaseous medium and catalyst particles to form a iiuidized mass and passing the last mentioned uidized mass through said passageway.

3. A process for carrying out exothermic reactions which comprises passing a mixture oi' finely divided catalyst particles in a gas as a iiuidized mass upwardly through a confined passageway formed by heat exchange tubes containing a heat exchange medium and arranged and terminating within a vessel, the heat evolved during the reaction being absorbed by the medium in said heat exchange tubes, separating some of th finely divided catalyst particles by reducing the velocity of the iiuidized mass as it leaves the top of the confined passageway, passing the separated hot catalyst particles over other fluid containing heat exchange tubes arranged in the space between said vessel and said passageway to remove additional heat from the catalyst particles and adding the separated cooled catalyst particles to additional'amounts o! gas and catalyst particles for passage through said confined passageway as a iiuldized mass.

4. A method of controlling the reaction temperature in an exothermic reaction which comprises passing a iiuidized mass of finely divided solid particles in a gaseous medium containing a reactant gas upwardly through a confined passageway formed with a heat exchange surface so that some of the heat liberated by the reaction is absorbed by the heat exchange surface. reducing .the velocity of the iiuidized mass as it leaves the top of the passageway to separate some of the finely divided solid particles from the iiuidized mass. dropping the separated particles over other heat exchange surfaces to cool the particles and returning the separated cooled solid particles to the confined passagewaywith additional reactant gas.

5. A vessel having an inlet and an outlet, a circle o! tubes positioned vertically within said vessel and terminating short of the ends of said vessel :to form a vertical central passageway, drums in said vessel associated with said tubes. a larger concentric circle of tubes adjacent the outer wall of said vessel also terminating short ci the ends of said vessel and associated with said drums, the tubes in said larger circle having bent portions to space them from the smaller circle of tubes, a conduit with one end positioned in the central passageway and the other end spaced a short distance from the inlet to the vessel thereby forming an annular gap, the said conduit being so arranged .that a iluidized mixture of finely divided solids in a gaseous suspension is passed through said passageway in direct contact with said smaller circle of tubes, and means so arranged as to cause some of the finely divided solids to be separated from the iiuidized mixture after it leaves said passageway and to cause the separated finely divided solids to descend in the annular passage formed by tubes in said larger circle and walls of the vessel and pass through the aforementioned gap to cause the descending fiuidized mixture to unite and be recirculated with the incoming mixture of gas and solids.

6. A vessel having an inlet and an outlet, a circle of heat exchange tubes positioned vertically within said vessel and terminating short oi' the ends of said vessel to form a vertical central passageway, drums in said vessel communicating with the ends of said tubes, a larger concentric circle of heat exchange tubes adjacent the outer wall of said vessel also terminating short of the ends of said vessel and communicating with said drums, the tubes in said larger circle having bent portions to space them from the smaller circle of tubes, a conduit with one end positioned in the central passageway and the other end spaced a short distance from the inlet to the vessel thereby forming an annular gap, the said conduit being so arranged that a fiuidized mixture of iinely di vided solids in a gaseous medium is introduced into said vessel, passed upwardly through said central passageway in contact with said smaller circle of tubes and means arranged so as to cause at least a portion of the fiuldized mixture leaving said passageway to be contacted with the larger circle of heat exchange tubes and said iluidized mixture caused to descend in the annular passage formed by the larger circle of tubes and the vessel walls and passed through the aforementioned gap to cause the descending fiuidized mixture to unite and recirculate with the incoming mixture oi gas and finely divided solids.

7. A vessel having an inlet and an outlet, a plurality of heat exchange tubes positioned vertically within said vessel and terminating short of the ends or said vessel to form a vertical passageway, another plurality oi' heat exchange tubes positioned vertically within said vessel also terminating short of the ends ci' said vessel and spaced from said tubes forming said passageway. a conduit with one end positioned in the vertical passageway and the other end spaced a short distance from .the inlet to the vessel thereby forming an annular gap, the said conduit being so arranged that a fluidiaed mass of solid particles is introduced through said inlet and is 'passed through said passageway in indirect heat exchange with said tubes forming said passageway and means whereby at least a portion of the iiuidized mass leaving said passageway is indirectly contacted with the other heat exchange tubes spaced from the tubes forming said passageway.

8. A vessel adapted for the treatment oi' gases and solids which comprises an outer closed shell, a plurality o! heat exchange tubes positioned in said shell torming an annulus and dividing said shell into an inner vertical passageway and an outer annular passageway, said heat exchange tubes being spaced from the ends o! said shell to provide communication between said inner pas- 25 sageway and said outer annular passageway at opposite ends ot said shell. an inlet conduit at the lower end of said shell for introducing a gaseous stream therein, e conduit with an end positioned in the inner passageway and the other end spaced a short distance from the inlet to the vessel thereby forming an annular gap, said inlet conduit being positioned to direct said gaseous stream upwardly through said inner passageway, an outlet conduit at the upper end oi' said shell for withdrawing the gaseous stream therefrom, said shell being adapted to contain a body of ilnely divided solid material which is circulated in an upward direction through said inner passageway by the gaseous stream rising therethrough and downwardly through said outer annular passageway, and means for maintaining a gas in admixture with said solids in said outer annular passageway in an amount suiilcient to maintain said solids in a tiuid state therein.

9. In the y apparatus defined by claim 8, the further improvement which comprises heat exchange means positioned in said outer annular passageway.

WALTER A. WURTH.

Disclaimer 2,383,836.Walier A. Warth Cranford, N. J. TEMPERATURE Common or CATA- atent dated Aug. 28, 1945. Disclaimer filed Aug. 11,

1948, by the assignee, Standard Oil Development Oompany.

Hereby enters this disclaimer of lclaim 4.

[Oficial Gazette Sept. 7, 1.948.]

the ends or said vessel to form a vertical passageway, another plurality oi' heat exchange tubes positioned vertically within said vessel also terminating short of the ends ci' said vessel and spaced from said tubes forming said passageway. a conduit with one end positioned in the vertical passageway and the other end spaced a short distance from .the inlet to the vessel thereby forming an annular gap, the said conduit being so arranged that a fluidiaed mass of solid particles is introduced through said inlet and is 'passed through said passageway in indirect heat exchange with said tubes forming said passageway and means whereby at least a portion of the iiuidized mass leaving said passageway is indirectly contacted with the other heat exchange tubes spaced from the tubes forming said passageway.

8. A vessel adapted for the treatment oi' gases and solids which comprises an outer closed shell, a plurality o! heat exchange tubes positioned in said shell torming an annulus and dividing said shell into an inner vertical passageway and an outer annular passageway, said heat exchange tubes being spaced from the ends o! said shell to provide communication between said inner pas- 25 sageway and said outer annular passageway at opposite ends ot said shell. an inlet conduit at the lower end of said shell for introducing a gaseous stream therein, e conduit with an end positioned in the inner passageway and the other end spaced a short distance from the inlet to the vessel thereby forming an annular gap, said inlet conduit being positioned to direct said gaseous stream upwardly through said inner passageway, an outlet conduit at the upper end oi' said shell for withdrawing the gaseous stream therefrom, said shell being adapted to contain a body of ilnely divided solid material which is circulated in an upward direction through said inner passageway by the gaseous stream rising therethrough and downwardly through said outer annular passageway, and means for maintaining a gas in admixture with said solids in said outer annular passageway in an amount suiilcient to maintain said solids in a tiuid state therein.

9. In the y apparatus defined by claim 8, the further improvement which comprises heat exchange means positioned in said outer annular passageway.

WALTER A. WURTH.

Disclaimer 2,383,836.Walier A. Warth Cranford, N. J. TEMPERATURE Common or CATA- atent dated Aug. 28, 1945. Disclaimer filed Aug. 11,

1948, by the assignee, Standard Oil Development Oompany.

Hereby enters this disclaimer of lclaim 4.

[Oficial Gazette Sept. 7, 1.948.] 

